Edition : the problem in my question was I've tried to find matrix S from equation 8 but this equation have error.

How to directly obtain right eigenvectors of matrix in R ? 'eigen()' gives only left eigenvectors

Really last edition, I've made big mess here, but this question is really important for me :

eigen() provides some matrix of eigenvectors, from function help :

" If ‘r <- eigen(A)’, and ‘V <- r$vectors; lam <- r$values’, then

                      A = V Lmbd V^(-1)                         

(up to numerical fuzz), where Lmbd =diag(lam)"

that is A V = V Lmbd, where V is matrix now we check it :


> A%*%V
                      [,1]                  [,2]          [,3]           [,4]
[1,]  0.0479968+0.5065111i  0.0479968-0.5065111i  0.2000725+0i  0.30290103+0i
[2,] -0.2150354+1.1746298i -0.2150354-1.1746298i -0.4751152+0i -0.76691563+0i
[3,] -0.2536875-0.2877404i -0.2536875+0.2877404i  1.3564475+0i  0.27756026+0i
[4,]  0.9537141-0.0371259i  0.9537141+0.0371259i  0.3245555+0i -0.03050335+0i
> V%*%Lmbd
                      [,1]                  [,2]          [,3]           [,4]
[1,]  0.0479968+0.5065111i  0.0479968-0.5065111i  0.2000725+0i  0.30290103+0i
[2,] -0.2150354+1.1746298i -0.2150354-1.1746298i -0.4751152+0i -0.76691563+0i
[3,] -0.2536875-0.2877404i -0.2536875+0.2877404i  1.3564475+0i  0.27756026+0i
[4,]  0.9537141-0.0371259i  0.9537141+0.0371259i  0.3245555+0i -0.03050335+0i

and I would like to find matrix of right eigenvectors R,
equation which define matrix of left eigenvectors L is :

L A  = LambdaM L

equation which define matrix of right eigenvectors R is :

A R = LambdaM R

and eigen() provides only matrix V:

A V = V Lmbd

I would like to obtain matrix R and LambdaM for real matrix A which may be negative-definite.

  • 1
    but transpose gives right eigenvectors of transposed matrix, doesn't it ? – Qbik Feb 16 '13 at 16:19
  • 3
    eigen() seems to me to be returning right eigenvectors, as I'd expect. Try this to see that it does: m <- matrix(1:4, ncol=2); e <- eigen(m); e$values[1]; (m %*% e$vectors[,1])/e$vectors[,1]. – Josh O'Brien Feb 16 '13 at 16:24
  • 1
    @BenBolker -- Compare these two to see that your bolded statement isn't true: W <- matrix(1:4, ncol=2); lambda <- diag(1:2); W %*% lambda; lambda %*% W. I think the OP's confusion is a (quite understandable) notational one. When W is a vector, right and left multiplication by the scalar lambda are equivalent, but the product is typically written like this: lamda W. When W is a matrix, it must be right-multiplied by the matrix Lambda, like this: W Lambda. (Compare equations (1) and (14) here, for example). – Josh O'Brien Feb 16 '13 at 19:36
  • 1
    still not quite right! see the Mathworld site referenced above. When expressed in terms of a single eigenvector/eigenvalue pair, A r == lambda r is true (eq. 1). When expressed in terms of the eigenvalue matrix, the correct expression is A R == R Lambda (eq. 14: in Mathworld's notation, A X_R == X_R D). So in fact what eigen is giving you is the right eigenvector matrix, as conventionally defined. I think you want something different, which is fine, but please be precise (and double-check my claims since I've already been wrong at least once). – Ben Bolker Feb 16 '13 at 22:05
  • 1
    @Josh O'Brien thank for your help ! I've implemented whole section 3 and it works as shown in section 4, there really was a mistake in definition (8). – Qbik Feb 17 '13 at 10:36

A worked example.

Default (= right eigenvectors):

m <- matrix(1:9,nrow=3)
e <- eigen(m)
e1 <- e$vectors
zapsmall((m %*% e1)/e1) ## right e'vec
##          [,1]      [,2] [,3]
## [1,] 16.11684 -1.116844    0
## [2,] 16.11684 -1.116844    0
## [3,] 16.11684 -1.116844    0

Left eigenvectors:

eL <- eigen(t(m))    
eL1 <- eL$vectors

(We have to go to a little more effort since we need to be multiplying by row vectors on the left; if we extracted just a single eigenvector, R's ignorance of row/column vector distinctions would make it "do the right thing" (i.e. (eL1[,1] %*% m)/eL1[,1] just works).)

zapsmall(t(eL1) %*% m/(t(eL1)))
##          [,1]      [,2]      [,3]
## [1,] 16.116844 16.116844 16.116844
## [2,] -1.116844 -1.116844 -1.116844
## [3,]  0.000000  0.000000  0.000000
  • 7
    I'm out of time for now for answering your edited question. You can try answering your own question based on what's been posted here so far, or wait for someone else to take a crack at it ... – Ben Bolker Feb 16 '13 at 17:00

This should work

Given a matrix A.

lefteigen  <-  function(A){

Every left eigenvector is the transpose of a right eigenvector of the transpose of a matrix


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